RU2804081C1 - Flexible screen cover, flexible display panel, flexible screen and foldable electronic device - Google Patents

Abstract

FIELD: flexible screens.

SUBSTANCE: group of inventions relates to a flexible screen cover, a flexible display panel, a flexible screen, and a foldable electronic device. A flexible screen is proposed, comprising: a protective layer, a base layer, a polarizer, a display layer, and a support layer, which are sequentially stacked on top of each other. The polarizer is located on the light-emitting side of the display layer. The support layer is located on the backlight side of the display layer. The flexible screen further comprises at least one of the first buffer layer, the second buffer layer, and the third buffer layer. The first buffer layer is located between the main layer and the polarizer, and both the ratio of the elastic moduli of the main layer and the first buffer layer and the ratio of the elastic moduli of the polarizer and the first buffer layer are from 2 to 500,000. The second buffer layer is located between the polarizer and the display layer, and both the ratio of the elastic moduli of the polarizer and the second buffer layer and the ratio of the elastic moduli of the display layer and the second buffer layer are from 2 to 500,000. The third buffer layer is located on the backlight side of the display layer. The third buffer layer and the support layer are stacked on top of each other, and the ratio of the elastic moduli of the support layer and the third buffer layer is from 2 to 500,000.

EFFECT: inventions make it possible to increase impact resistance of a flexible screen.

16 cl, 17 dwg

Description

Field of technology

[0001] The present invention relates to the field of display technology and, in particular, to a flexible screen cover, a flexible display panel, a flexible screen and a foldable electronic device.

State of the art

[0002] A foldable flexible screen revolutionizes the experience of people on a regular mobile phone screen. The flexible screen uses flexible organic polymer material, and the strength of the flexible screen is much less than that of a normal mobile phone screen. Therefore, the impact resistance of the flexible screen is relatively low. The closest analogues of the present invention are disclosed in publications WO 2019013366 and CN 110647213.

The essence of the invention

[0003] The present invention provides a flexible screen cover, a flexible display panel, a flexible screen, and a foldable electronic device for improving the impact resistance of the flexible screen.

[0004] According to a first aspect, the present invention provides a flexible screen cover. The flexible screen cover is configured to cover the flexible display panel, protect the flexible display panel, and provide a touch interface for the user. The flexible screen cover has the characteristics of flexibility and bending, and includes a protective layer, a base layer and a buffer layer, which are stacked on top of each other in series. The ratio of the elastic moduli of the main layer and the buffer layer is from 8 to 180000. The protective layer is configured to protect the main layer to improve the reliability of the main layer. The protective layer can be made of flexible and bend-resistant organic polymer material. The base layer may be made of a high modulus material, wherein the base layer has a relatively high resistance to deformation. The buffer layer may be made of a low modulus translucent material, with the buffer layer located close to the flexible display panel.

[0005] The flexible screen cover is subjected to a momentary impact, and the mechanical scenario of the flexible screen cover can be analyzed using stress wave theory in dynamic mechanics. According to the stress wave theory, the ratio of the elastic modulus of the base layer material and the buffer layer is from 8 to 180000 (including extreme values). In other words, the elastic modulus of the base layer is much larger than the elastic modulus of the buffer layer, and the wave impedance difference between the base layer and the buffer layer is quite large. In addition, the deformation of the buffer layer is within an appropriate range and is not excessive, so that a relatively stable interface between the buffer layer and the base layer can be maintained. Therefore, the stress wave generated by the transient impact can be adequately reflected at the interface between the main layer and the buffer layer, so that most of the energy is taken away by the reflected stress wave, and the transmitted stress wave enters the buffer layer with less energy. Consequently, the flexible display panel also receives less impact energy. This can effectively reduce the impact on the flexible display panel and effectively reduce the risk of damage to the flexible display panel. Therefore, placing the buffer layer on one side of the base layer and ensuring that the ratio of the modulus of elasticity of the base layer and the buffer layer is in the proper range of 8 to 180,000 can improve the impact resistance ability of the flexible screen.

[0006] In an embodiment, the buffer layer is in direct contact with the base layer. Direct contact means they are layered directly without the need for additional adhesive. For example, the buffer layer can be formed on the surface of the base layer by a coating process such as spraying or screen printing, or the attachment of the buffer layer to the base layer can be accomplished by first laminating and then curing. Direct contact can reduce the deformation of the base layer upon impact, avoid the damage to the base layer caused by excessive deformation, improve the reliability of the flexible screen cover, and improve the impact resistance performance of the flexible screen.

[0007] In an embodiment, the elongation at break of the buffer layer to the base layer is greater than or equal to 2. When the base layer is subjected to impact, the buffer layer can provide resistance to the base layer to resist deformation of the base layer, thereby reducing the risk of damage to the base layer and improving performance impact resistance of the flexible screen cover and the entire flexible screen.

[0008] In an embodiment, the base layer is made of ultra-thin glass, the flexible screen cover includes a reinforcement layer, the reinforcement layer and the base layer are stacked between the protective layer and the base layer, and the elastic modulus of the reinforcement layer is equal to or greater than 1 MPa. The reinforcing layer can be made, for example, of a polymeric material such as acrylate, polyurethane, polyester, polyimide or epoxy resin. The arrangement of the reinforcing layer can improve the strength of the base layer made of ultra-thin glass and reduce the risk of breakage of the base layer, so that the impact resistance performance of the flexible screen cover and the entire flexible screen can be improved.

[0009] In an embodiment, the reinforcing layer is in direct contact with the base layer; in other words, the reinforcing layer and the base layer are not glued together using an additionally applied adhesive, but are directly laminated/layered. For example, the reinforcing layer may be formed directly on the surface of the base layer during the coating process; or the reinforcing layer is an adhesive film for directly bonding the reinforcing layer and the base layer. Impact testing confirms that the direct contact method provides an optimal protection effect for the base layer, reducing the risk of breakage of the base layer.

[0010] In an embodiment, the base layer is made of colorless polyimide, and the elastic modulus ratio of the base layer and the buffer layer is from 8 to 16000. Because the colorless polyimide has relatively good toughness, and the elongation at break of the colorless polyimide can reach from 15% to 40 %, the base layer made of colorless polyimide can be well adapted to the bending scenario. In addition, setting the ratio of the modulus of elasticity of such a base layer and the buffer layer to 8 to 16,000 can improve the impact resistance ability of the flexible screen with such a base layer.

[0011] In one embodiment, the buffer layer is made of a polyurethane elastomer, an acrylate elastomer, or a polysiloxane elastomer. These materials are stable and have reliable performance, so that an energy reflection surface can be well formed between these materials and the base layer.

[0012] In an embodiment, the protective layer includes a first protective layer and a second protective layer that are stacked on top of each other, wherein the second protective layer is located between the first protective layer and the base layer, and the elastic modulus of the first protective layer is at the gigapascal (GPa) level ). For example, the first protective layer may be made from an organic polymeric material such as aramid, clear polyimide or polyethylene terephthalate. The second protective layer may use colorless polyimide. The elastic modulus of the first protective layer may be greater than or equal to the elastic modulus of the second protective layer. Providing two protective layers can increase the protective thickness of the flexible screen cover, and using a material with a higher elastic modulus to make the outer first protective layer can increase the resistance of the flexible screen cover to deformation. Typically, this design improves the impact resistance of the flexible screen cover and the flexible screen itself.

[0013] In one embodiment, the reinforcement layer may be formed through a reinforcement process on a surface of the first protective layer that is remote from the second protective layer. The arrangement of the reinforcement layer can improve the abrasion resistance and hardness of the first protective layer, as well as improve user touch feedback.

[0014] According to a second aspect, the present invention provides a flexible display panel. The flexible display panel includes a first buffer layer, a polarizer, a second buffer layer and a display layer, which are sequentially stacked on each other, wherein the polarizer is located on the light-emitting side of the display layer, the elastic modulus ratio of the polarizer and the first buffer layer is from 4 to 10000, and the elastic modulus ratio of the polarizer and the second buffer layer is from 4 to 10000. The flexible display panel can be used together with a flexible screen cover, and the flexible display panel can be an OLED display panel. The material type and parameter value of each of the first buffer layer and the second buffer layer may be the same as the material type and parameter value of the previous buffer layer. The display layer includes an OLED component, and the display layer can emit light under the action of an electric field to realize display.

[0015] According to the voltage wave theory, since the difference in wave impedance between the polarizer and the first buffer layer and the second buffer layer on both sides of the polarizer is relatively large and in the proper range, the energy of the voltage wave attenuated at the interface between the main layer and the first buffer layer is is attenuated at the interface between the first buffer layer and the polarizer, and is further attenuated at the interface between the polarizer and the second buffer layer, so that the energy that ultimately enters the display layer is greatly reduced, thereby effectively reducing the risk of damage to the display layer and avoiding abnormal display, in other words, improving the impact resistance characteristics of the flexible display panel and flexible screen.

[0016] In an embodiment, the polarizer is in direct contact with the second buffer layer. Direct contact means that they are laminated directly, without the use of additional adhesive. For example, the buffer layer can be formed on the surface of the polarizer through a coating process such as sputtering or screen printing, or the attachment of the buffer layer to the polarizer can be achieved by first laminating and then curing. Direct contact can reduce the deformation of the polarizer upon impact and avoid the damage to the polarizer caused by excessive deformation.

[0017] In one embodiment, the first buffer layer is made of a polyurethane elastomer, acrylate elastomer, or polysiloxane elastomer, and/or the second buffer layer is made of a polyurethane elastomer, acrylate elastomer, or polysiloxane elastomer. The materials of the first buffer layer and the second buffer layer may be the same or different. The materials are stable and have reliable performance, so the energy reflection surface can be well formed between the materials and the polarizer.

[0018] In one embodiment, the flexible display panel includes a third buffer layer and a support layer, wherein the third buffer layer, the support layer and the display layer are stacked one above the other and located on the backlight side of the display layer, and the ratio of the moduli of elasticity of the support layer and the third buffer layer is from 2 to 500,000. The third buffer layer can be made of low modulus material, and the third buffer layer can be translucent or non-transparent. The support layer is used as the back support and protective structure of the entire flexible display panel. The support layer can be made of a metallic material such as titanium alloy, stainless steel, copper foil or magnesium-aluminum alloy, or a high modulus organic material such as clear polyimide, aramid or polyethylene terephthalate. There may be one third buffer layer and one support layer. In this case, one of them is close to the display layer and the other is far from the display layer.

[0019] According to the stress wave theory, since the interface between the support layer and the third buffer layer is formed between the high modulus material and the low modulus material, the stress wave energy from the back surface of the flexible display panel can be attenuated, so that the energy that ultimately enters the display layer is reduced, thereby reducing the impact on the display layer and effectively softening the impact on the rear surface of the flexible display panel.

[0020] In an embodiment, there is at least one support layer and there are at least two third buffer layers, wherein the at least one support layer and at least two third buffer layers are alternately stacked on each other, one of the third buffer layers is adjacent to the display layer, and the display layer and all auxiliary layers are respectively located on two opposite sides of the third buffer layer adjacent to the display layer. In other words, starting from the display layer, the flexible display panel has the structural form of a display layer, a third buffer layer, a support layer, a third buffer layer, and the like. Based on the actual number of third buffer layers and the actual number of support layers, the layer furthest away from the display layer may be the third buffer layer or the support layer, and the layer closest to the backlight side of the display layer is one of the third buffer layers. The interface formed between the high modulus material and the low modulus material can increase the attenuation of voltage wave energy, thereby further reducing the impact on the display layer and significantly reducing the impact on the rear surface of the flexible display panel.

[0021] In an embodiment, the third buffer layer is made of a polyurethane elastomer, acrylate elastomer, polysiloxane elastomer, acrylate foam, polyurethane foam, polystyrene material, polyethylene material, ethylene-propylene terpolymer, or ethylene vinyl acetate copolymer material. The materials are stable and have reliable performance, and can participate well in forming the energy reflection interface.

[0022] According to a third aspect, the present invention provides a flexible screen. The flexible screen includes a protective layer, a base layer, a polarizer, a display layer and a support layer, which are sequentially stacked on each other, wherein the polarizer is located on the light-emitting side of the display layer, and the support layer is located on the backlight side of the display layer. The flexible screen further includes at least one of a first buffer layer, a second buffer layer and a third buffer layer; particularly includes only a first buffer layer, a second buffer layer, or a third buffer layer, or includes a first buffer layer and a second buffer layer, or includes a first buffer layer and a third buffer layer, or includes a second buffer layer and a third buffer layer, or includes a first buffer layer, a second buffer layer, and a third buffer layer. In the solution in which the first buffer layer is included, the first buffer layer is located between the main layer and the polarizer, and both the ratio of the elastic moduli of the main layer and the first buffer layer and the ratio of the elastic moduli of the polarizer and the first buffer layer are from 2 to 500,000. In the solution , in which the second buffer layer is included, the second buffer layer is located between the polarizer and the imaging layer, and both the ratio of the elastic moduli of the polarizer to the second buffer layer, and the ratio of the elastic moduli of the imaging layer to the second buffer layer is from 2 to 500000. In a solution in which a third buffer layer is included, the third buffer layer is located on the backlight side of the display layer, the third buffer layer and the support layer are stacked on each other, and the elastic modulus ratio of the support layer and the third buffer layer is from 2 to 500,000.

[0023] Placing the buffer layer at any suitable location on the flexible screen and ensuring that the ratio of the modulus of elasticity of the adjacent layer (the layer adjacent to the buffer layer, including the display layer and excluding the adhesive layer) and the buffer layer falls within the appropriate range of 2 to 500,000 , can create a stable interface between high modulus material and low modulus material, thereby improving the impact resistance of the flexible screen.

[0024] In an embodiment where the flexible screen includes a first buffer layer or a second buffer layer, the first buffer layer is made of a polyurethane elastomer, an acrylate elastomer, or a polysiloxane elastomer, and the second buffer layer is made of a polyurethane elastomer, an acrylate elastomer, or a polysiloxane elastomer. When the flexible screen includes a third buffer layer, the third buffer layer is made of a polyurethane elastomer, acrylate elastomer, polysiloxane elastomer, acrylate foam, polyurethane foam, polystyrene material, polyethylene material, ethylene propylene terpolymer material, or ethylene vinyl acetate copolymer material. In this embodiment, the fact that the flexible screen includes a first buffer layer means that the first buffer layer is located between the base layer and the polarizer. Likewise, that the flexible screen includes a second buffer layer means that the second buffer layer is located between the polarizer and the display layer, and that the flexible screen includes a third buffer layer means that the third buffer layer is located on the rear side. illumination of the display layer of the screen. The first buffer layer, the second buffer layer and the third buffer layer, which are made using appropriate materials, have reliable characteristics so that the energy reflecting interface can be well formed.

[0025] In accordance with a fourth aspect, the present invention provides a foldable electronic device. The foldable electronic device includes a housing and a flexible screen, the flexible screen being mounted in the housing. The housing may be used as an external part or a non-external part of a foldable electronic device. The body can be folded and unfolded. When the housing is folded, the flexible screen can be housed in the housing, in other words, a foldable electronic device is an electronic device with the screen folded inward; or when the case is folded, the flexible screen is located on the outside of the case, in other words, a foldable electronic device is an electronic device with the screen folded outward. The flexible screen of the foldable electronic device has better shock resistance.

Brief description of drawings

[0026] FIG. 1 is a schematic side view of a structure of a foldable electronic device in a folded state according to Embodiment 1;

[0027] FIG. 2 is a schematic diagram of the foldable structure of the foldable electronic device of FIG. 1 unfolded;

[0028] FIG. 3 is a block diagram of a side view of the flexible screen layer of the foldable electronic device shown in FIG. 2;

[0029] FIG. 4 is a block diagram of another side view of the flexible screen layer of the foldable electronic device shown in FIG. 2;

[0030] FIG. 5 is a block diagram of another side view of the flexible screen layer of the foldable electronic device shown in FIG. 2;

[0031] FIG. 6 is a block diagram of a side view of a buffer film layer used to make the first buffer layer of the flexible screen of FIG. 5;

[0032] FIG. 7 - schematic representation of the principle of the wave theory of stress;

[0033] FIG. 8 is a schematic illustration of a mechanical scenario in which the flexible screen cover of FIG. 3 is exposed to a voltage wave;

[0034] FIG. 9 is a schematic illustration of a mechanical scenario in which the flexible screen cover of FIG. 5 is exposed to a voltage wave;

[0035] FIG. 10 is a schematic diagram of a mechanical scenario in which the flexible display panel of the flexible screen of FIG. 5 is exposed to a voltage wave;

[0036] FIG. 11 is a schematic structure diagram of a side view of a flexible display panel layer according to Embodiment 2;

[0037] FIG. 12 is a schematic structure diagram of a side view of a flexible display panel layer according to Embodiment 3;

[0038] FIG. 13 is a schematic structure diagram of a side view of a flexible display panel according to Embodiment 4;

[0039] FIG. 14 is a schematic structure diagram of a side view of a flexible display panel according to Embodiment 5;

[0040] FIG. 15 is a schematic structure diagram of a side view of a flexible screen according to another embodiment;

[0041] FIG. 16 is a schematic structure diagram of a side view of a flexible screen according to another embodiment; And

[0042] FIG. 17 is a schematic structure diagram of a side view of a flexible screen according to another embodiment.

Description of Embodiments of the Invention

[0043] The following embodiments of the present invention provide a foldable electronic device, including, but not limited to, a foldable mobile phone, a foldable tablet computer, and the like. As shown in FIG. 1 and 2, the foldable electronic device 10 includes a first housing 11, a hinge 12, a second housing 13, and a flexible shield 14.

[0044] As shown in FIG. 1, a hinge 12 is located between the first housing 11 and the second housing 13. The hinge 12 may be a mechanism including multiple components, and the hinge 12 may produce movement of the mechanism. Two opposite sides of the hinge 12 are respectively connected to the first body 11 and the second body 13, so that the first body 11 and the second body 13 rotate relative to each other.

[0045] In Embodiment 1, both the first housing 11 and the second housing 13 can be used as external parts of the foldable electronic device 10, that is, as open parts that can be directly observed by the user. In another embodiment, the foldable electronic device 10 may include a housing used as an external part, and both the first housing 11 and the second housing 13 may be installed in the housing as non-external parts. The first housing 11 and the second housing 13 are designed for installing and carrying the flexible screen 14.

[0046] The flexible screen 14 has the characteristics of flexibility and bending. When the foldable electronic device 10 in Embodiment 1 is in a folded state, the flexible shield 14 may be placed between the first housing 11 and the second housing 13; in other words, the foldable electronic device 10 may be an electronic device with a screen folded inward. In another embodiment, when the foldable electronic device 10 is in a folded state, the flexible screen 14 is located on the outside, and the first housing 11 and the second housing 13 are located on the inside; in other words, the foldable electronic device 10 may be an electronic device with an outwardly folded screen.

[0047] As shown in FIG. 3, the flexible screen 14 may include a flexible screen cover 15 and a flexible display panel 16, and the flexible screen cover 15 covers the flexible display panel 16. The flexible screen cover 15 is designed to be touched by the user and may protect the flexible display panel 16.

[0048] As shown in FIG. 3, in Embodiment 1, the flexible screen cover 15 may include a first protective layer 151, a second protective layer 152, a base layer 153, and a first buffer layer 155. The first protective layer 151, the second protective layer 152, the base layer 153, and the first buffer layer 155 are sequentially stacked on each other, the first protective layer 151 is located away from the flexible display panel 16, and the first buffer layer 155 is located near the flexible display panel 16.

[0049] The base layer 153 may be made of a high modulus material and therefore has a relatively high deformation resistance ability. For example, the base layer 153 may be made of Ultra Thin Glass (UTG) or Colorless Polyimide (CPI). The modulus of UTG ranges from 60 GPa to 90 GPa, the typical modulus value can be 60 GPa, 70 GPa or 90 GPa, and UTG has quite high deformation resistance ability. In addition, the UTG does not have a creep phenomenon (a phenomenon in which the deformation increases with time when the stress in the solid material is constant), and after bending, the UTG does not bend when re-expanded, so that the flatness requirement of the flexible screen cover 15 can be ensured. The modulus of CPI ranges from 5 GPa to 8 GPa, the typical modulus value can be 5 GPa, 6 GPa or 8 GPa, and CPI also has relatively high deformation resistance ability. In addition, CPI has relatively good toughness, and the elongation at break (the ratio of the length of elongation to the length before elongation, when the material is stretched to break under the tensile force) of CPI can reach 15% to 40%, and good adaptation to bending scenario. The thickness of the base layer 153 can be calculated based on requirements. For example, when UTG is used, the thickness may be from 30 µm to 100 µm, and a typical thickness value may be 30 µm, 70 µm or 100 µm; when CPI is used, the thickness can range from 20 µm to 80 µm, and a typical thickness value can be 20 µm, 50 µm, 80 µm or 100 µm.

[0050] Both the first protective layer 151 and the second protective layer 152 are designed to protect the base layer 153. Both the first protective layer 151 and the second protective layer 152 can be made of organic polymeric materials and are flexible and resistant to bending. The second protective layer 152 includes, but is not limited to, a film layer made of CPI, and its thickness can be calculated based on requirements, for example, from 20 μm to 80 μm.

[0051] The first protective layer 151 may use an organic polymer material with a modulus at the GPa level, such as an aramid (Aramid) with a modulus of 8 GPa to 12 GPa (typical modulus may be 8 GPa, 10 GPa, or 12 GPa) and thickness 15 µm to 40 µm (typical thickness may be 15 µm, 25 µm or 40 µm), CPI with modulus from 5 GPa to 8 GPa (typical modulus may be 5 GPa, 6 GPa or 8 GPa) and thickness from 20 µm to 80 µm (typical thickness may be 20 µm, 50 µm, 80 µm or 100 µm), or polyethylene terephthalate (polyethylene terephthalate, abbreviated PET) with a modulus of 1 GPa to 5 GPa (typical modulus may be 1 GPa, 3 GPa or 5 GPa) and thicknesses from 30 µm to 100 µm (typical thicknesses may be 30 µm, 50 µm or 100 µm). Based on actual requirements, the first protective layer 151 may be composed of one layer of film or at least two layers of laminated film made of the same material, or may be at least two layers of laminated film made of different materials ( each layer of film is made of a separate material). The first protective layer 151 has a relatively high modulus of elasticity and has a relatively high resistance to deformation. Adding a first protective layer 151 on top of a second protective layer 152 may increase the thickness of the protective layer.

[0052] In another embodiment, to improve the abrasion resistance and hardness of the first protective layer 151 and improve the user's touch feedback (so that the user's touch is relatively hard rather than soft), a reinforcement layer can be formed through a hardening process on the surface of the first a protective layer 151 remote from the second protective layer 152; and/or the flexible screen cover 15 may have only one protective layer, and the material characteristics of one protective layer may be determined based on a requirement that is not limited to the above description.

[0053] In an actual application scenario (for example, during an impact test such as a pen drop test, a ball drop test, or a whole device drop test), the impact on the flexible screen cover 15 is a momentary impact, and a transient voltage is generated internally the flexible screen cover 15 when the flexible screen cover 15 is subjected to a momentary impact. Since the first protective layer 151 is added to thicken and strengthen the protective layer above the flexible screen cover 15, the protective layer can withstand transient stresses so that the protective layer is prevented from being punctured and the base layer 153 is prevented from being damaged. For example, it is confirmed by an impact test that the base layer 153 made of UTG is not brittle after adding the first protective layer 151 to the base layer 153. Thus, the impact resistance of the flexible screen cover 15 is improved. Since the impact resistance performance of the flexible screen cover 15 is improved, the impact resistance performance of the entire flexible screen 14 can be improved.

[0054] As shown in FIG. 4, particularly when the base layer 153 is a UTG film layer, given that the UTG is brittle, the reinforcement layer 156 may cover the base layer 153, and the reinforcement layer 156 is sandwiched between the second protective layer 152 and the base layer 153. The reinforcement layer 156 may be made, for example, of a polymeric material such as acrylate, polyurethane, polyester, polyimide or epoxy resin, and the modulus of the material of the reinforcing layer 156 is at least 1 MPa (the higher the better). The arrangement of the reinforcing layer 156 can improve the strength of the base layer 153 and reduce the risk of breakage of the base layer 153, so that the impact resistance performance of the flexible screen cover 15 and the entire flexible screen 14 can be improved. In addition, it is confirmed through an impact test that when the reinforcement layer 156 is in direct contact with the base layer 153 (in other words, the reinforcement layer 156 and the base layer 153 are not connected by an additionally applied adhesive; for example, the reinforcement layer 156 can be formed directly on the surface of the base layer 153 during the coating process or the reinforcement layer 156 is an adhesive film for directly bonding the reinforcing layer 156 and the base layer 153), the protection effect of the base layer 153 is optimal, and the risk of breakage of the base layer 153 is the lowest. Of course, the reinforcing layer 156 and the base layer 153 may alternatively be joined using additional adhesive.

[0055] In another embodiment, the reinforcing layer 156 may alternatively be applied to the flexible screen cover 15, the base layer 153 of which is a CPI film layer. Alternatively, the design of the reinforcing layer 156 may be eliminated.

[0056] The first buffer layer 155 may be made of a low modulus translucent material (modulus may range from 500 kPa to 1 GPa, and a typical modulus value may be 500 kPa, 10 MPa, 100 MPa, or 1 GPa), such as polyurethane elastomer, acrylate elastomer or polysiloxane elastomer. As shown in FIG. 3 or 4, the first buffer layer 155 and the base layer 153 may be joined by an adhesive layer 154, and the adhesive layer 154 may be, for example, an optically clear adhesive (OCA) or a pressure-sensitive adhesive (CPA). pressure adhesive, abbreviated as PSA).

[0057] Alternatively, as shown in FIG. 5, the first buffer layer 155 may be in direct contact with the base layer 153. For example, the first buffer layer 155 may be formed on the surface of the base layer 153 through a coating process such as sputtering or screen printing, or by bonding the first buffer layer 155 to the base layer. 153 can be realized first by lamination and then by polymerization. In particular, as shown in FIG. 6, a buffer film (the curing rate may be less than 70%) can be first made from a buffer material, and the buffer film includes a high-release film A, an incompletely cured buffer adhesive 155' and an easy-release film B, which are stacked on each other in series. friend. Before lamination, the light release film B in the buffer film is peeled off, and the non-fully cured buffer adhesive 155' is laminated onto the surface of the base layer 153 through a lamination process (eg, roll lamination or vacuum lamination). Then, the chemical group in the incompletely cured buffer adhesive 155' is completely reacted by the heating or ultraviolet light curing process so that a first buffer layer 155 is formed on the surface of the base layer 153. When the first buffer layer 155 and the flexible display panel 16 are laminated sequentially, peel-off the film A on the surface of the first buffer layer 155 is peeled off.

[0058] As described above, the flexible screen cover 15 is subjected to a momentary impact, and the mechanical scenario of the flexible screen cover 15 can be analyzed using stress wave theory in dynamic mechanics.

[0059] When a medium is exposed to an external shock load, the particles of the medium that are directly affected by the shock load are the first to leave the initial equilibrium position. Because there is relative motion (deformation) between these media particles and neighboring media particles, these media particles are subject to a force (namely stress) generated by the neighboring media particles, but also create a reaction force on the neighboring media particles. Therefore, neighboring particles of the medium also leave the initial equilibrium position and move. Therefore, the disturbance of the medium caused by the external shock load gradually spreads from near to far in the medium, forming a stress wave.

[0060] As shown in FIG. 7, according to the voltage wave theory, the voltage wave is reflected and transmitted at the interface of two media with different characteristic impedances, the energy of the reflected voltage wave does not transfer to the neighboring medium, and the energy of the transmitted voltage wave continues to be transmitted to the next carrier through the interface. The energy of the reflected voltage wave accumulates over time. Based on the fact that the total energy of the voltage wave is fixed, if the energy of the reflected voltage wave increases, the energy of the transmitted wave decreases. A large difference in wave impedances between the media on either side of the interface indicates greater energy of the reflected stress wave at the interface and less energy of the transmitted stress wave at the interface. When a stress wave enters medium 2 with low wave resistance from medium 1 with high wave resistance, the speed of the particle at the interface increases compared to the speed of the particle adjacent to the interface in medium 1, and, consequently, the generation of deformation of the particle at the interface accelerates. In addition, the occurrence of deformation on particles adjacent to the interface in medium 1 and medium 2 is correspondingly accelerated; in other words, the occurrence of deformation in medium 1 and medium 2 is accelerated. Moreover, if the wave impedance difference between the two media is relatively large, the deformation generated by medium 1 is relatively large. On the contrary, if the difference in characteristic impedances between the two media is relatively small, the deformation created by medium 1 is relatively small. In addition, the characteristic impedance of the medium Z = , where E is the modulus of the material, and - density of the material. To be specific, a higher modulus of a material (a material with a higher modulus usually also has a higher density) indicates greater characteristic impedance.

[0061] With reference to stress wave theory, the following continues with a detailed description of Embodiment 1 separately for a solution in which the base layer 153 and the first buffer layer 155 are connected by an adhesive, and a solution in which the base layer 153 is in direct contact with the first buffer layer layer 155.

[0062] (1) A solution in which the base layer 153 and the first buffer layer 155 are connected with an adhesive

[0063] Compared to the base layer 153, the adhesive is a highly deformable material (similar to an adhesive glue) with an extremely low modulus (typically less than 100 kPa, where, for example, the OCA modulus may be 30 kPa), and the modulus ratio (modulus ratio) of the base layer 153 and the adhesive layer is extremely large (for example, greater than or equal to 1800000); in other words, the difference in wave resistance between them is extremely large. Due to the product thickness requirements, the thickness of the adhesive layer is quite small (eg 25 µm or 50 µm). As shown in FIG. 8, the stress wave enters the flexible shield cover 15 of the protective layer and propagates to the interface between the base layer 153 and the adhesive layer 154. According to the stress wave theory, the stress wave can be reflected and transmitted at the interface a, which accelerates the occurrence of deformation mainly layer 153 and an adhesive layer 154. Since the adhesive layer 154 is highly deformable and has a fairly thin thickness, the adhesive layer 154 is almost "squeezed out" by the base layer 153 in a fairly short time (in this case, the base layer 153 is in approximately direct contact with the first buffer layer 155 ), so interface a is “damaged” in a fairly short time. Therefore, the stress wave cannot be adequately reflected by the boundary between the base layer 153 and the adhesive layer 154, and the transmitted stress wave carries more energy and continues to propagate downward. In other words, the adhesive layer 154 has almost no effect on the energy of the reflected stress wave under the above thickness limitation.

[0064] When the voltage wave continues to be transmitted to the first buffer layer 155, since the base layer 153 is in approximately direct contact with the first buffer layer 155, an interface can be considered to be formed between the base layer 153 and the first buffer layer 155. The modulus ratio of the base layer 153 to the first buffer layer 155 may be from 8 to 180,000, and a typical modulus ratio may be 8, 600, or 180,000. For example, the modulus ratio of the UTG material base layer 153 to the first buffer layer 155 may be from 60 to 180,000. and a typical modulus ratio may be 60, 700, 7000, or 180,000; The modulus ratio of the base layer 153 of the CPI material to the first buffer layer 155 may be from 8 to 16000, and a typical modulus ratio may be 8, 60, 600, or 16000. It can be learned that the modulus ratio of the base layer 153 to the first buffer layer 155 and the waveform difference the resistances between them are relatively large, but less than the ratio of the modules of the base layer 153 to the adhesive layer 154 and the difference in characteristic impedance between them.

[0065] According to the stress wave theory, the stress wave can be reflected and transmitted at the interface between the main layer 153 and the first buffer layer 155, and deformation occurs at the main layer 153 and the first buffer layer 155. Because the modulus (500 kPa to 1 GPa) The first buffer layer 155 is much larger than the modulus (less than 100 kPa) of the adhesive layer 154, the first buffer layer 155 is less susceptible to deformation than the adhesive layer 154, so that the interface between the main layer 153 and the first buffer layer 155 can exist more stably. Thus, the voltage wave can be relatively adequately reflected by the interface between the main layer 153 and the first buffer layer 155, so that the energy of the transmitted voltage wave is relatively small, and the energy received by the flexible display panel 16 below the first buffer layer is also relatively small.

[0066] It can be learned that the flexible screen cover 15 for which the first buffer layer 155 is disposed can attenuate the voltage wave energy, reduce the impact on the flexible display panel 16, and effectively reduce the risk of damage to the flexible display panel 16. This improves the impact resistance of the flexible screen cover 15 and the entire flexible screen 14.

[0067] (2) A solution in which the base layer 153 is in direct contact with the first buffer layer 155

[0068] As shown in FIG. 9, in solution (2), no adhesive layer is applied, and a section b is formed directly between the base layer 153 and the first buffer layer 155. The fundamental analysis of solution (2) is consistent with the analysis when a stress wave is applied to the first buffer layer 155 in solution (1 ). Thus, solution (2) can also improve the impact resistance of the flexible screen cover 15 and the entire flexible screen 14.

[0069] Moreover, in solution (1), the modulus ratio (greater than or equal to 1,800,000) of the base layer 153 to the adhesive layer 154 is extremely large, and therefore the deformation of the base layer 153 is relatively large. In solution (2), the modulus ratio (8 to 180,000) of the base layer 153 to the first buffer layer 155 is relatively small, and therefore the deformation of the base layer 153 is relatively small. Reducing the deformation of the base layer 153 can prevent damage to the base layer 153 caused by excessive deformation. In particular, for the base layer 153 made of frangible UTG, using a solution where the UTG is in direct contact with the first buffer layer 155 avoids excessive deformation of the UTG and reduces the risk of UTG failure. Of course, for the base layer 153 made of non-fragile CPI, using a solution where the CPI is in direct contact with the first buffer layer 155 also avoids excessive deformation of the CPI. This is also an improvement in the impact resistance of the flexible screen cover 15 and the entire flexible screen 14.

[0070] In conclusion, in Embodiment 1, placing the first buffer layer 155 under the main layer 153 and ensuring that the modulus ratio of the main layer 153 and the first buffer layer 155 is in the proper range can reduce the deformation of the flexible screen cover 15, improve the self-protection performance and the reliability of the flexible screen cover 15 and improve the impact resistance of the flexible screen 14.

[0071] In Embodiment 1, the elongation at break (elongation ratio at break) of the materials from the first buffer layer 155 to the base layer 153 may be greater than or equal to 2, and a typical value may be 25. For example, the elongation at break of the first buffer layer 155 to base layer 153 of UTG material may be greater than or equal to 10, and a typical value may be 10, 40, or 100; The elongation at break of the first buffer layer 155 to the base layer 153 of CPI material may be greater than or equal to 2, and a typical value may be 2, 16, or 25. This indicates that the first buffer layer 155 is stronger and less brittle than the base layer layer 153. When the base layer 153 is struck, the first buffer layer 155 may provide resistance to the base layer 153 to resist deformation of the base layer 153, thereby reducing the risk of damage to the base layer 153 and improving the impact resistance performance of the flexible screen cover 15 and the entire flexible screen 14. B In particular, for a base layer 153 made of brittle UTG, placing a stronger first buffer layer 155 can significantly reduce the risk of UTG failure.

[0072] It can be understood that the calculation of the elongation at break is independent of the above calculation of the modulus ratio of the base layer 153 and the first buffer layer 155, and the impact resistance of the flexible screen 14 can be improved regardless of whether one or both of the structures are used.

[0073] As shown in FIG. 10, in Embodiment 1, the flexible display panel 16 may be an organic light emitting diode (OLED) flexible display panel. The flexible display panel 16 may include a polarizer 161, a second buffer layer 162, and a display layer 163 that are stacked in series.

[0074] The display layer 163 may include an OLED component and may emit light under the influence of an electric field to realize display. The side from which the display layer 163 can emit light is called the light-emitting side (eg, the top side in FIG. 10); the side opposite to the light emitting side does not emit light and may be referred to as the backlight side (eg, the bottom side in FIG. 10). The polarizer 161 is located on the light-emitting side of the display layer 163 and is located between the first buffer layer 155 and the display layer 163. The modulus of the polarizer 161 may be from 2 GPa to 5 GPa, and a typical value may be 2 GPa, 3.5 GPa, or 5 GPa. The modulus ratio of the polarizer 161 and the first buffer layer 155 may be from 4 to 10,000, such as 4, 350, or 10,000. This indicates that the modulus difference between the polarizer 161 and the first buffer layer 155 is relatively large, and therefore the wave impedance difference is also relatively large.

[0075] The material type and material parameter of the second buffer layer 162 may be the same as that of the first buffer layer 155. For example, the second buffer layer 162 may also be made of a low modulus (modulus can range from 500 kPa to 1 GPa) translucent material, prone to deformation, for example, polyurethane elastomer, acrylate elastomer or polysiloxane elastomer. The modulus ratio of the polarizer 161 and the second buffer layer 162 may be from 4 to 10,000, such as 4, 350, or 10,000. This indicates that the modulus difference between the polarizer 161 and the second buffer layer 162 is relatively large, and the wave impedance difference between them is also relatively large. The second buffer layer 162 may be in direct contact with the polarizer 161. For example, the second buffer layer 162 may be formed on the surface of the polarizer 161 by a coating process such as sputtering or screen printing, or attaching the second buffer layer 162 to the base layer 153 may be realized by first lamination and subsequent curing (which is similar to the previous description, and the details will not be repeated here). The second buffer layer 162 and the polarizer 161 may be joined by an adhesive, and the adhesive may be, for example, OCA or PSA.

[0076] It can be obtained by analysis using the above voltage wave theory that since the differences in wave impedance between the polarizer 161 and the first buffer layer 155 and the second buffer layer 162 on both sides of the polarizer 161 are relatively large and within the proper range, the energy The voltage wave attenuated at the interface b between the base layer 153 and the first buffer layer 155 is attenuated at the interface c between the first buffer layer 155 and the polarizer 161, and is further attenuated at the interface d between the polarizer 161 and the second buffer layer 162, so that the energy ultimately entering the display layer 163 is greatly reduced, thereby effectively reducing the risk of damage to the display layer 163 and avoiding abnormal display. In addition, through analysis, it can also be obtained that the solution in which the polarizer 161 is in direct contact with the second buffer layer 162 avoids excessive deformation of the polarizer 161 and reduces the risk of damage to the polarizer 161.

[0077] Therefore, placing one buffer layer on the top side and bottom side of the polarizer 161 and ensuring that the modulus ratio of the polarizer 161 and the buffer layer is in the proper range can improve the impact resistance performance of the flexible display panel 16 and the flexible screen 14. For example, with Using the pen drop impact test, it is confirmed that after using the solution of Embodiment 1, the corresponding pen drop height when a color spot (a tiny small bright dot that appears in the display area) is created on the flexible display panel 16 is significantly improved, which means that The impact resistance characteristics of the flexible display panel 16 are significantly improved.

[0078] In the above description, the first buffer layer 155 is used as a component of the flexible screen cover 15. Of course, the first buffer layer 155 may alternatively belong to the flexible display panel 16. Since the flexible screen cover 15 and the flexible display panel 16 are finally assembled into the flexible screen 14, the solution of Embodiment 1 can effectively improve the impact resistance performance of the flexible screen 14 in any manner.

[0079] Since the rear surface of the flexible display panel 16 corresponds to the body and the hinge, the rear surface of the flexible display panel 16 is exposed to these structures, and therefore, the buffer layer can be further located on the backlight side of the display layer 163. The following will be a detailed description.

[0080] As shown in FIG. 11, in Embodiment 2, based on the above solution of Embodiment 1, the back film 164, the third buffer layer 165 and the support layer 166 are sequentially stacked on the backlight side of the display layer 163.

[0081] The back film 164 supports and protects the display layer 163. The thickness of the back film 164 can be from 20 μm to 100 μm, and the modulus can be from 1 GPa to 10 GPa.

[0082] The third buffer layer 165 may be made of a material such as a polyurethane elastomer, acrylate elastomer, polysiloxane elastomer, acrylate foam, polyurethane foam, polystyrene, polyethylene material, ethylene-propylene terpolymer, or ethylene-vinyl acetate copolymer. The third buffer layer 165 is located on the backlight side of the display layer 163 and, therefore, can be made of a translucent or opaque material. The thickness of the third buffer layer 165 can range from 10 μm to 300 μm. The third buffer layer 165 has a low modulus of elasticity, for example, from 500 kPa to 1 GPa, and is susceptible to deformation. The modulus ratio of the back film 164 and the third buffer layer 165 may be from 2 to 20,000, and a typical modulus ratio may be 2, 500, or 20,000. This indicates that the modulus difference and the characteristic impedance difference between the back film 164 and the third buffer layer 165 relatively large.

[0083] The support layer 166 is used as a back support and protective structure for the entire flexible display panel 16. The thickness of the support layer 166 can range from 20 microns to 200 microns. The support layer 166 may be made of a metallic material such as titanium alloy (modulus may range from 50 GPa to 150 GPa), stainless steel (modulus may range from 150 GPa to 250 GPa), copper foil, or magnesium-aluminum alloy (modulus may range from 150 GPa to 250 GPa). range from 30 GPa to 100 GPa). Alternatively, the support layer 166 may be made from a high modulus organic material such as CPI, aramid, or PET. The modulus ratio of the support layer 166 to the third buffer layer 165 may be from 2 to 500,000, and a typical value may be 2, 2000, or 500,000. It can be learned that the modulus difference and the characteristic impedance difference between the support layer 166 and the third buffer layer 165 are relatively large.

[0084] It can also be obtained by analysis using the above voltage wave theory that since the third buffer layer 165 with a relatively low modulus is located between the back film 164 and the support layer 166, and it is ensured that the modulus ratios of the back film 164 and the third buffer layer 165 and the support layer 166 and the third buffer layer 165 are in proper ranges, two interfaces between the high modulus material and the low modulus material can be created so that the voltage wave energy from the rear surface of the flexible display panel 16 is attenuated by half, and the energy ultimately entering the display layer 163 is greatly reduced, thereby greatly reducing the impact on the display layer 163 and effectively reducing the impact on the flexible display panel 16 caused by the body and the hinge.

[0085] In another embodiment, a buffer layer may be further added on the backlight side of the display layer 163 to add an interface between the high modulus material and the low modulus material, increase the attenuation of voltage wave energy, and further reduce the impact on the display layer 163.

[0086] As shown in FIG. 12, in Embodiment 3, one third buffer layer 165 is located on the upper side and lower side of the support layer 166; in other words, the two third buffer layers 165 and the support layer 166 are alternately stacked on top of each other, and the outer third buffer layer 165 is used as the layer furthest from the display layer 163.

[0087] Alternatively, as shown in FIG. 13, in Embodiment 4, two third buffer layers 165 and two support layers 166 are arranged on the backlight side of the display layer 163, two third buffer layers 165 and two support layers 166 are alternately stacked on each other, and the outer support layer 166 is used as a layer, furthest from the display layer 163.

[0088] Alternatively, as shown in FIG. 14, in Embodiment 5, three third buffer layers 165 and two support layers 166 are arranged on the backlight side of the display layer 163, three third buffer layers 165 and two support layers 166 are alternately stacked on each other, and the outer third buffer layer 165 is used as a layer , furthest from the display layer 163.

[0089] It can be understood that in another embodiment, an alternately stacked structure of another number of third buffer layers 165 and another number of support layers 166 can be designed based on the requirement and is not limited to the above description.

[0090] It can be understood that in another embodiment, provided that the interface between the high modulus material and the low modulus material is created by placing the buffer layer at any appropriate position of the flexible screen 14 and ensuring the modulus ratio of the adjacent layer (the layer adjacent to the buffer layer, including the display layer and excluding the adhesive layer) and the buffer layer to fall within the proper range (for example, 2 to 500,000), the impact resistance performance of the entire flexible screen 14 can be improved.

[0091] For example, as shown in FIG. 15, only one buffer layer 155 (namely, the first buffer layer 155) may be disposed between the main layer 153 of the flexible screen cover 15 and the polarizer 161 of the flexible display panel 16, so that the modulus ratio of the main layer 153 and the buffer layer 155 is from 8 to 180000. Alternatively, as shown in FIG. 16, only one buffer layer 162 (namely, the second buffer layer 162) can be located between the polarizer 161 and the display layer 163 of the flexible display panel 16, so that the module ratio of the polarizer 161 and the buffer layer 162 is 4 to 10000, and the module ratio of the display layer 163 and buffer layer 162 is from 2 to 500,000. Alternatively, as shown in FIG. 17, only one buffer layer 165 (namely, the third buffer layer 165) may be disposed between the back film 164 and the support layer 166 of the flexible display panel 16, so that the module ratio of the back film 164 and the buffer layer is from 2 to 20,000, and the ratio modules of the support layer 166 and the third buffer layer 165 range from 2 to 500,000.

[0092] From the above description, it can be learned that regardless of whether the flexible screen cover has a buffer layer or the flexible display panel has a buffer layer, the impact resistance performance of the flexible screen into which the flexible screen cover and the flexible display panel are assembled can be improved. In other words, both the joint arrangement of the flexible screen cover with the buffer layer and the conventional flexible display panel, and the joint arrangement of the conventional flexible screen cover and the flexible display panel with the buffer layer can improve the impact resistance performance of the flexible screen.

[0093] In prior embodiments of the present invention, any two adjacent layers of flexible screen 14 may be bonded together by adhesive or in direct contact depending on product requirements that are not emphasized elsewhere unless otherwise noted.

[0094] The above description represents only specific embodiments of this application and is not intended to limit the scope of protection of the present invention. Any changes or substitutions obvious to those skilled in the art within the technical scope disclosed in this application should fall within the scope of protection of this invention. Therefore, the scope of protection of the present invention should correspond to the scope of protection of the claims.

Claims (25)

1. Flexible screen containing: a protective layer, a base layer, a polarizer, a display layer, and a support layer, which are sequentially stacked on each other, wherein the polarizer is located on the light-emitting side of the display layer, the support layer is located on the backlight side of the display layer, and the flexible screen further includes at least one from a first buffer layer, a second buffer layer and a third buffer layer, wherein: the first buffer layer is located between the main layer and the polarizer, and both the ratio of the elastic moduli of the main layer and the first buffer layer and the ratio of the elastic moduli of the polarizer and the first buffer layer are from 2 to 500,000; a second buffer layer is disposed between the polarizer and the display layer, and both the elastic modulus ratio of the polarizer and the second buffer layer and the elastic modulus ratio of the display layer and the second buffer layer are from 2 to 500,000; And the third buffer layer is located on the backlight side of the display layer, the third buffer layer and the support layer are stacked on top of each other, and the ratio of the modulus of elasticity of the support layer and the third buffer layer is from 2 to 500,000. 2. Flexible screen according to claim 1, in which, when the flexible screen includes a first buffer layer or a second buffer layer, the first buffer layer is made of a polyurethane elastomer, an acrylate elastomer or a polysiloxane elastomer, and the second buffer layer is made of a polyurethane elastomer, an acrylate elastomer or a polysiloxane elastomer; or, when the flexible screen includes a third buffer layer, the third buffer layer is made of a polyurethane elastomer, acrylate elastomer, polysiloxane elastomer, acrylate foam, polyurethane foam, polystyrene material, polyethylene material, ethylene-propylene terpolymer material or ethylene-vinyl acetate copolymer material. 3. A foldable electronic device containing: a housing and a flexible screen according to claim 1 or 2, wherein the flexible screen is installed in the housing. 4. A flexible screen cover for a flexible screen according to claim 1, comprising: a protective layer, a base layer and a buffer layer, which are sequentially stacked on top of each other, wherein the ratio of the elastic moduli of the base layer and the buffer layer ranges from 8 to 180,000. 5. The flexible screen cover according to claim 4, wherein the buffer layer is in direct contact with the main layer. 6. The flexible screen cover according to claim 4 or 5, in which the elongation coefficient when breaking the buffer layer to the main layer is greater than or equal to 2. 7. Flexible screen cover according to any one of claims. 4-6, in which the main layer is made of ultra-thin glass, and the cover of the flexible screen contains a reinforcing layer, and the reinforcing layer is laid between the protective layer and the main layer, and the elastic modulus of the reinforcing layer is greater than or equal to 1 MPa. 8. Flexible screen cover according to any one of claims. 4-6, in which the main layer is made of colorless polyimide, and the ratio of the elastic modulus of the main layer and the buffer layer is from 8 to 16000. 9. Flexible screen cover according to any one of claims. 4-8, in which the buffer layer is made of a polyurethane elastomer, an acrylate elastomer or a polysiloxane elastomer. 10. Flexible screen cover according to any one of claims. 4-9, in which the protective layer comprises a first protective layer and a second protective layer that are stacked on top of each other, wherein the second protective layer is located between the first protective layer and the base layer, and the elastic modulus of the first protective layer is from 1 to 12 GPa. 11. A flexible display panel for a flexible screen according to claim 1, comprising: a first buffer layer, a polarizer, a second buffer layer and a display layer, which are sequentially stacked on top of each other, wherein the polarizer is located on the light-emitting side of the display layer, the ratio of the elastic moduli of the polarizer and the first buffer layer is from 4 to 10000, and the ratio of the elastic moduli of the polarizer and the second buffer layer is from 4 to 10000. 12. The flexible display panel of claim 11, wherein the polarizer is in direct contact with the second buffer layer. 13. The flexible display panel of claim 11 or 12, wherein the first buffer layer is made of a polyurethane elastomer, an acrylate elastomer, or a polysiloxane elastomer, and/or the second buffer layer is made of a polyurethane elastomer, an acrylate elastomer, or a polysiloxane elastomer. 14. Flexible display panel according to any one of claims. 11-13, comprising at least one third buffer layer and at least one support layer, wherein the third buffer layer, the support layer and the display layer are stacked on each other and all located on the backlight side of the display layer, and the ratio of the modulus of elasticity of the support layer and third buffer layer is from 2 to 500,000. 15. The flexible display panel of claim 14, wherein there is at least one support layer and at least two third buffer layers, wherein the at least one support layer and the at least two third buffer layers are alternately stacked on each other. , one of the third buffer layers is adjacent to the display layer, and the display layer and all support layers are respectively located on two opposite sides of the third buffer layer adjacent to the display layer. 16. The flexible display panel of claim 14 or 15, wherein the third buffer layer is made of a polyurethane elastomer, acrylate elastomer, polysiloxane elastomer, acrylate foam, polyurethane foam, polystyrene material, polyethylene material, ethylene-propylene terpolymer, or ethylene-vinyl acetate copolymer.

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